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Accurate large-scale simulations of siliceous zeolites by neural network potentials

Andreas Erlebach, Petr Nachtigall, Lukáš Grajciar

2022npj Computational Materials64 citationsDOIOpen Access PDF

Abstract

Abstract The computational discovery and design of zeolites is a crucial part of the chemical industry. Finding highly accurate while computational feasible protocol for identification of hypothetical siliceous frameworks that could be targeted experimentally is a great challenge. To tackle this challenge, we trained neural network potentials (NNP) with the SchNet architecture on a structurally diverse database of density functional theory (DFT) data. This database was iteratively extended by active learning to cover not only low-energy equilibrium configurations but also high-energy transition states. We demonstrate that the resulting reactive NNPs retain DFT accuracy for thermodynamic stabilities, vibrational properties, as well as reactive and non-reactive phase transformations. As a showcase, we screened an existing zeolite database and revealed >20k additional hypothetical frameworks in the thermodynamically accessible range of zeolite synthesis. Hence, our NNPs are expected to be essential for future high-throughput studies on the structure and reactivity of siliceous zeolites.

Topics & Concepts

ReaxFFDensity functional theoryArtificial neural networkZeoliteComputer scienceChemistryComputational chemistryMolecular dynamicsMachine learningCatalysisBiochemistryInteratomic potentialMachine Learning in Materials ScienceZeolite Catalysis and SynthesisX-ray Diffraction in Crystallography
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